Led light assembly and  system

ABSTRACT

An LED based light assembly and lighting system is disclosed. The lighting system includes at least one light assembly comprising a plurality of LED chips, a controller and a power supply module. The controller is configured to receive an input signal and to provide an output control signal for controlling power to the at least one light assembly. The power supply module is configured to receive a standard voltage and current signal and to provide a power signal to the at least one light assembly to power the at least one light assembly in response to the control signal.

RELATED APPLICATIONS

This application is a continuation of and claims the benefit under 35U.S.C. §120 to U.S. patent application Ser. No. 14/104,564 filed Dec.12, 2013, entitled “LED LIGHT ASSEMBLY AND SYSTEM”; which claims thebenefit under U.S.C. §119(e) to U.S. Provisional Application Ser. No.61/736,317 filed Dec. 12, 2012, entitled “LIGHT ASSEMBLY AND SYSTEM,”and to U.S. Provisional Application Ser. No. 61/864,256 filed Aug. 9,2013, entitled “LIGHT ASSEMBLY AND SYSTEM,” the content of each of thepreceding is herein incorporated by reference in its entirety.

BACKGROUND

Overhead light fixtures used in parking garages, office space,industrial warehouses, and the like often include fluorescent lightbulbs or lamps, and typically include 3 fluorescent light bulbs. Somedisadvantages of fluorescent light bulbs or lamps that are used in suchfixtures are that they are not very efficient and thus consume a lot ofpower. For example, such fluorescent light bulbs or lamps are not veryamenable to being dimmed and when they are dimmed their power factor orefficiency drops down to about 70%. In addition, fluorescent light bulbsmay not provide enough light for certain fixture locations. Further,fluorescent light bulbs have an omni-directional light output pattern,not directional, and thus there is inherent loss of light radiated in abackwards direction (upwards instead of downwards). Further, fluorescentlight bulbs become less efficient over time and use, and are notsuitable for use in certain applications such as cold weather locations.Still further, fluorescent light bulbs tend to give off a large amountof heat, which can lead to increased air conditioning costs when used inhigh temperature locations and climates.

SUMMARY OF INVENTION

Aspects and embodiments are directed to a replacement light assembly foruse in fixtures that currently use fluorescent light bulbs or lamps.Aspects and embodiments are further directed to replacement lightingsystems for use in applications that currently use fluorescent lightfixtures. In particular, aspects and embodiments of the light assemblydisclosed herein can be used to replace existing 2-foot, 4-foot, 8-footor any length tubular fluorescent light bulbs. Further, aspects andembodiments of the lighting system systems disclosed herein can beconfigured to retro-fit existing overhead light fixtures or can beprovided as new light fixtures. Further, aspects and embodiments of thelight assembly and lighting systems disclosed herein can be configuredto replace any type of fluorescent light bulb or lamp. Further, aspectsand embodiments of the light assembly and lighting system disclosedherein provide for using less light assemblies than fluorescent bulbscurrently used in existing fixtures, while providing more efficient,longer-life, and cooler (less heat being generated) lighting.

Various aspects and embodiments of an LED based light assembly andlighting system are disclosed. One embodiment of a lighting systemincludes at least one light assembly comprising a plurality of LEDchips, a controller and a power supply module. The controller isconfigured to receive an input signal and to provide an output controlsignal for controlling power to the at least one light assembly. Thepower supply module is configured to receive a standard voltage andcurrent signal and to provide a power signal to the at least one lightassembly to power the at least one light assembly in response to thecontrol signal.

Another embodiment of a lighting system includes at least one lightassembly comprising a plurality of LED chips, a controller configured toreceive an input signal and to provide an output control signal forcontrolling power to the at least one light assembly, and a power supplymodule configured to receive a standard voltage and current signal, toconvert the standard voltage and current signal to a DC voltage signalfor powering the controller and to provide a power signal to the atleast one light assembly to power the at least one light assembly inresponse to the control signal.

The various embodiments of the lighting system can further comprise amulti-setting switch that provides a respective switch output signal foreach setting of the switch, wherein the controller is responsive toswitch output signal and is configured to provide the control signal tocontrol the power level provided by the at least one light assembly inresponse to the setting of the multi-setting switch.

The various embodiments of the lighting system can further comprise anambient light sensor that senses an amount of ambient light and providesan ambient light sensor output signal as a function of an amount ofsensed ambient light, wherein the controller is also responsive to theambient light sensor output signal and is configured to provide thecontrol signal to control the light level provided by the at least onelight assembly in response to an amount of sensed ambient light.

The various embodiments of the lighting system can further comprise amotion sensor that senses motion and provides a motion sensor outputsignal, wherein the controller is also responsive to the motion sensoroutput signal and is configured to provide the control signal to controlthe light level provided by the at least one light assembly in responseto sensed motion.

According to aspects of the various embodiments of the lighting system,the at least one light assembly is sized and configured to bereplacement for a standard fluorescent light bulb.

According to aspects of the various embodiments of the lighting system,the at least one light assembly comprises a circuit board housing aplurality of LED chips arranged in at least one row, wherein the circuitboard is configured so as to dispose the plurality of LED chips in aspaced apart relationship so as to keep the LED chips below a maximumoperating temperature. According to aspects of the light assembly, thecircuit board is laid out so to provide for a high level of heatdissipation. According to aspects of the light assembly, the lightassembly further comprises a base having a plurality of arms that defineridges along the length of the base to receive the circuit board.According to aspects of the light assembly, the light assembly furthercomprises further comprises at least one end cap that comprises twoconnectors that are configured and arranged to mate with a standardfluorescent light bulb fixture. According to aspects of the variousembodiments of the lighting system, lighting system further comprises anoverdraft protection circuit that limits a peak amount of current thatcan be provided between the two pins of the end cap.

According to aspects of the various embodiments of the lighting system,the power supply comprises a stable voltage and current maintenancecircuit that that limit the maximum current and voltage to be providedto the at last one light assembly.

According to aspects of the various embodiments of the lighting system,the at least one light assembly further comprises a cover having ridgesrunning along a length of the cover so as to disperse the light providedby the plurality of LED chips along a width of the cover and the lightassembly.

According to aspects of the various embodiments of the lighting system,the lighting system is sized and arranged to be a replacement for astandard overhead fluorescent light fixture.

According to aspects of the various embodiments of the lighting system,the lighting system comprises at least two light assemblies. Accordingto aspects of the various embodiments of the lighting system, thelighting system further comprises a cover that covers that at least twolight assemblies, wherein the cover has ridges running along a length ofthe cover so as to disperse the light provided by at least two lightassemblies along a width of the cover and along a width of the lightingsystem. According to aspects of the various embodiments of the lightingsystem, the lighting system further comprises two rods that maintain thecover in place over the by at least two light assemblies. According toaspects of the various embodiments of the lighting system, the lightingsystem further comprises a reflective background having ridges toreflect the light provided by the at least two light assemblies.

According to aspects of the various embodiments of the lighting system,the lighting system further comprises a frame for the lighting systemhaving a plurality of slots in two ends of the frame; a plurality ofbracket pins, each shaped and arranged to be pushed through slots in theframe and into an end of a base of the light assembly.

According to aspects of the various embodiments of the lighting system,the lighting system further comprises a respective hanging bracket andtwo clips for each of the two ends of the frame of the lighting systemthat are constructed and arranged to allow for easy installation andremoval of each end of the frame of the lighting system from a casingfor the lighting system.

According to aspects of the various embodiments of the lighting system,the lighting system further comprises a plurality of clamps thatmaintain the cover to a base of the lighting system.

An LED based lighting system, comprises at least one light assemblycomprising a plurality of LED chips; a controller configured to receivean input signal and to provide an output control signal for controllingpower to the at least one light assembly; and a power supply moduleconfigured to receive a standard voltage and current signal, to convertthe standard voltage and current signal to a DC voltage signal forpowering the controller and to provide a power signal to the at leastone light assembly to power the at least one light assembly in responseto the control signal.

The LED based lighting system as disclosed in any embodiment herein, canfurther comprise a multi-setting switch that provides a respectiveswitch output signal for each setting of the switch, wherein thecontroller is responsive to switch output signal and is configured toprovide the control signal to control the power level provided by the atleast one light assembly in response to the setting of the multi-settingswitch.

The LED based lighting system as disclosed in any embodiment herein, canfurther comprise a ambient light sensor that senses an amount of ambientlight and provides an ambient light sensor output signal as a functionof an amount of sensed ambient light, wherein the controller is alsoresponsive to the ambient light sensor output signal and is configuredto provide the control signal to control the light level provided by theat least one light assembly in response to an amount of sensed ambientlight.

The LED based lighting system as disclosed in any embodiment herein, canfurther comprise a motion sensor that senses motion and provides amotion sensor output signal, wherein the controller is also responsiveto the motion sensor output signal and is configured to provide thecontrol signal to control the light level provided by the at least onelight assembly in response to sensed motion.

The LED based lighting system as disclosed in any embodiment herein,wherein the at least one light assembly is sized and configured to bereplacement for a standard fluorescent light bulb.

The LED based lighting system as disclosed in any embodiment herein,wherein the at least one light assembly comprises a circuit boardhousing a plurality of LED chips arranged in at least one row, whereinthe circuit board is configured so as to dispose the plurality of LEDchips in a spaced apart relationship so as to keep the LED chips below amaximum operating temperature.

The LED based lighting system as disclosed in any embodiment herein,wherein the circuit board is laid out so to provide for a high level ofheat dissipation.

The LED based lighting system as disclosed in any embodiment herein,wherein the at least one light assembly is further comprises a basehaving a plurality of arms that define ridges along the length of thebase to receive the circuit board.

The LED based lighting system as disclosed in any embodiment herein,wherein the at least one light assembly further comprises at least oneend cap that comprises two connectors that are configured and arrangedto mate with a standard fluorescent light bulb fixture.

The LED based lighting system as disclosed in any embodiment herein, canfurther include an overdraft protection circuit that limits peak amountof current that can be provided between the two pins of the end cap.

The LED based lighting system as disclosed in any embodiment herein,wherein the power supply comprises a stable voltage and currentmaintenance circuit that that limit the maximum current and voltage tobe provided to the at last one light assembly.

The LED based lighting system as disclosed in any embodiment herein,wherein the at least one light assembly further comprises a cover havingridges running along a length of the cover so as to disperse the lightprovided by the plurality of LED chips along a width of the cover andthe light assembly.

The LED based lighting system as disclosed in any embodiment herein,wherein the lighting system is sized and arranged to be a replacementfor a standard overhead fluorescent light fixture.

The LED based lighting system as disclosed in any embodiment herein,wherein the lighting system comprises at least two light assemblies.

The LED based lighting system as disclosed in any embodiment herein, canfurther comprise a cover that covers that at least two light assemblies,wherein the cover has ridges running along a length of the cover so asto disperse the light provided by at least two light assemblies along awidth of the cover and along a width of the lighting system.

The LED based lighting system as disclosed in any embodiment herein, canfurther comprise two rods that maintain the cover in place over the byat least two light assemblies.

The LED based lighting system as disclosed in any embodiment herein, canfurther comprise a reflective background having ridges to reflect thelight provided by the at least two light assemblies.

The LED based lighting system as disclosed in any embodiment herein, canfurther comprise a frame for the lighting system having a plurality ofslots in two ends of the frame and a plurality of bracket pins, eachbracket pin being shaped and arranged to be pushed through correspondingslots in the frame and into an end of a base of the light assembly.

The LED based lighting system as disclosed in any embodiment herein, canfurther comprise a respective hanging bracket and two clips for each ofthe two ends of the frame of the lighting system that are constructedand arranged to allow for easy installation and removal of each end ofthe frame of the lighting system from a casing for the lighting system.

The LED based lighting system as disclosed in any embodiment herein, canfurther comprise a plurality of clamps that maintain the cover to a baseof the lighting system.

BRIEF DESCRIPTION OF THE DRAWINGS

Various aspects of at least one embodiment are discussed below withreference to the accompanying figures, which are not intended to bedrawn to scale. The figures are included to provide illustration and afurther understanding of the various aspects and embodiments, and areincorporated in and constitute a part of this specification, but are notintended as a definition of the limits of the invention. Where technicalfeatures in the figures, detailed description or any claim are followedby references signs, the reference signs have been included for the solepurpose of increasing the intelligibility of the figures anddescription. In the figures, each identical or nearly identicalcomponent that is illustrated in various figures is represented by alike numeral. For purposes of clarity, not every component may belabeled in every figure. In the figures:

FIG. 1 is a schematic diagram of a lighting system according to thedisclosure;

FIG. 2 is a top view of a lighting assembly according to the disclosure;

FIG. 3 is a bottom view of the lighting assembly according to thedisclosure;

FIGS. 4A-4E are mechanical drawings of the lighting assembly 104;

FIG. 5 illustrates a lighting fixture retrofitted with two lightingassemblies LED light assemblies mounted in the fixture;

FIG. 6 is a mechanical drawing of an end cap of the light assemblyaccording to this disclosure;

FIG. 7 is a perspective view of an LED light bulb without its cover,according to this disclosure;

FIG. 8 illustrates a multi-layer board including a plurality of LEDchips slid into engagement with a base, according to this disclosure;

FIG. 9 is a perspective view of a top of a base according to thisdisclosure;

FIG. 10 is a perspective view of a bottom of the base according to thisdisclosure;

FIG. 11 is a mechanical drawing of the base according to thisdisclosure;

FIG. 12 is a schematic diagram of on embodiment two LED arrays accordingto this disclosure;

FIG. 13 is a rendering of the layers of the multi-layer board accordingto this disclosure;

FIG. 14 is a mechanical drawing of the cover of the LED bulb accordingto this disclosure;

FIGS. 15A-C. are a schematic view of one embodiment of a power supplyaccording to the disclosure;

FIG. 16 is a perspective view on one embodiment of a power supply moduleaccording to the disclosure;

FIG. 17 is a schematic of a rectifying and smoothing circuit of thepower supply circuit according to the disclosure;

FIG. 18 is a schematic of a controller circuit according to thedisclosure;

FIG. 19 is a schematic of a stable current and voltage maintenancecircuit according to the disclosure;

FIG. 20 illustrates an embodiment of the sensors mounted in an existinglight fixture according to the disclosure;

FIG. 21 is a schematic diagram of sensors according to the disclosure;

FIG. 22 is a schematic diagram of a microcontroller according to thedisclosure;

FIG. 23 illustrates a schematic diagram of one embodiment of amulti-position switch according to the disclosure;

FIG. 24 illustrates a table of switch settings for the lighting assemblyaccording to this disclosure;

FIG. 25 illustrates a flow chart of current provided to the LED's of thelighting assembly for the switch configured with a first setting as afunction of light sensed by an ambient light sensor;

FIG. 26 illustrates a flow chart of current provided to the LED's of thelighting assembly for the switch configured with a second setting as afunction of light sensed by an ambient light sensor;

FIG. 27 illustrates a flow chart of current provided to the LED's of thelighting assembly for the switch configured with a third setting as afunction of light sensed by an ambient light sensor;

FIG. 28 illustrates a flow chart of current provided to the LED's of thelighting assembly for the switch configured with a fourth setting as afunction of motion sensed by a motion sensor;

FIG. 29 illustrates a flow chart of current provided to the LED's of thelighting assembly for the switch configured with a fifth setting as afunction of motion sensed by an motion sensor; and

FIG. 30 illustrates a flow chart of current provided to the LED's of thelighting assembly for the switch configured with a sixth setting as afunction of motion sensed by a motion sensor;

FIG. 31 is a photo of a front view of a second embodiment of a lightingsystem according to this disclosure;

FIG. 32 is a photo of an exploded view of a portion of the lightassembly showing a portion of the two light assemblies, a portion of thecover, and a portion of the rods for holding the cover of this secondembodiment;

FIG. 33 is a photo of a cover for the light assembly having corrugationsof this second embodiment;

FIG. 34 illustrates a rear view of this second embodiment of thelighting system having slots in the reflector;

FIG. 35 shows a photo of an exploded view of bracket pins inserted intoa portion of the frame of the lighting system of this second embodiment;

FIG. 36 shows a bracket pin inserted into the end of the base of thelighting assembly of this second embodiment;

FIG. 37 is a mechanical drawing of the bracket pin of this secondembodiment;

FIG. 38 is mechanical drawing of a portion of the frame including slotsfor receiving the bracket pin of this second embodiment;

FIG. 39 is a photo of a perspective view of the hanging bracket of thissecond embodiment;

FIG. 40 is a mechanical drawing of the hanging bracket;

FIG. 41 illustrates a third embodiment of a lighting system according tothis disclosure;

FIG. 42 illustrates a holding structure for holding sensors and forproviding a conduit for coupling the sensors to the controller of thepower supply module for this third embodiment;

FIG. 43 illustrates a power supply module housed within the lightingsystem on a back side of a base plate that secures the light assembliesof this third embodiment;

FIG. 44 is an exploded view of a front view of a portion of the lightingsystem without its cover showing a portion of the two light assembliessecured to the base plate by rounded snap brackets of this thirdembodiment;

FIG. 45 is a mechanical drawing of a perspective view, side view andbottom view of the rounded snap brackets for this third embodiment; and

FIG. 46 shows a perspective view, end view and schematic view of aconnector used to connect lighting assembly to the power supply moduleof this third embodiment.

DETAILED DESCRIPTION

Aspects and embodiments are directed to a replacement light assembly foruse in fixtures that currently use fluorescent light bulbs or lamps.Aspects and embodiments are further directed to replacement lightingsystems for use in applications that currently use fluorescent lightfixtures. In particular, aspects and embodiments of the light assemblydisclosed herein can be used to replace existing 2-foot, 4-foot, 8-footor any length tubular fluorescent light bulbs. Further, aspects andembodiments of the lighting system systems disclosed herein can beconfigured to retro-fit existing overhead light fixtures or can beprovided as new light fixtures. Further, aspects and embodiments of thelight assembly and lighting systems disclosed herein can be configuredto replace any type of fluorescent light bulb or lamp. Further, aspectsand embodiments of the light assembly and lighting system disclosedherein provide for using less light assemblies than fluorescent bulbscurrently used in existing fixtures, while providing more efficient,longer-life, and cooler (less heat being generated) lighting.

It is to be understood that the term light bulb and lamp are usedinterchangeably herein. It is to be appreciated that embodiments of themethods and apparatuses discussed herein are not limited in applicationto the details of construction and the arrangement of components setforth in the following description or illustrated in the accompanyingdrawings. The methods and apparatuses are capable of implementation inother embodiments and of being practiced or of being carried out invarious ways. Examples of specific implementations are provided hereinfor illustrative purposes only and are not intended to be limiting. Inparticular, acts, elements and features discussed in connection with anyone or more embodiments are not intended to be excluded from a similarrole in any other embodiment.

Also, the phraseology and terminology used herein is for the purpose ofdescription and should not be regarded as limiting. Any references toembodiments or elements or acts of the systems and methods hereinreferred to in the singular may also embrace embodiments including aplurality of these elements, and any references in plural to anyembodiment or element or act herein may also embrace embodimentsincluding only a single element. The use herein of “including,”“comprising,” “having,” “containing,” “involving,” and variationsthereof is meant to encompass the items listed thereafter andequivalents thereof as well as additional items. References to “or” maybe construed as inclusive so that any terms described using “or” mayindicate any of a single, more than one, and all of the described terms.Any references to front and back, left and right, top and bottom, upperand lower, and vertical and horizontal are intended for convenience ofdescription, not to limit the present systems and methods or theircomponents to any one positional or spatial orientation.

FIG. 1 is a schematic diagram of an embodiment of a lighting system 100according to the disclosure. The lighting system includes a power supplymodule 102 that receives an input voltage, such as for example astandard 110-220 Volts AC or any other standard input voltage andcurrent, and converts the standard input voltage and current to DCoutput voltage for powering a light assembly 104, ambient light andmotion sensors 106, and a microcontroller 108. The lighting system alsoincludes a multiple position switch 110, which can be for example a DIPswitch having at least 3 switches.

The power supply module 102 receives, for example, a 120 Volts AC inputsignal on input line 130 and converts the input voltage to two paralleloutput DC voltage signals on lines 132, 134 to power two LED bulbs orlamps 104. The power supply module converts the input voltage andcurrent to a DC voltage and current for powering the microcontroller108. The power supply module can also include the microcontroller 108,which is configured to be responsive to the switch 110 settings toprovide an output signal on lines 132, 134 that adjust the amount oflight output by the LED light assemblies 104. The sensor circuit 106includes a motion sensor circuit that detects motion to provide forturning on the LED light assemblies 104 in response to the detectedmotion. The sensor circuit also includes an ambient light sensorcircuit, which outputs a signal corresponding to an amount of detectedambient light. The microcontroller 108 in combination with the motionsensor of sensors 106 combine to provide an output signal that turns onthe LED light assemblies 104 in response to motion detected by themotion sensor. In addition, the microcontroller 108 in combination withthe ambient light sensor of sensors 106 combine to provide an outputsignal that adjusts the amount of light output by LED light assemblies104. For example, if no ambient light is detected by the light sensor144, then the light assemblies can provide a maximum light output.Alternatively, if a sufficient amount of ambient light is detected, suchas may occur in daylight, then LED light assemblies can be controlled,for example to only provide half of the light capacity of the LED lightbulbs or lamps.

FIG. 2 is a photo of a top view of a portion of one embodiment of thelighting assembly 104 according to the disclosure. The lighting assembly104 includes a cover 116 and an end cap 112 that mates the lightingassembly 104 to existing lighting fixtures for fluorescent light bulbs.FIG. 3 is a photo of a bottom view of one embodiment the lightingassembly 104 according to the disclosure. The lighting assembly includesa base 118. FIGS. 4A-4E are a mechanical drawings of the lightingassembly 104 including top view 4A, side view 4B, bottom view 4C of thelighting assembly 104, and FIGS. 4D and 4E are end views of an end cap112.

As noted above, the lighting assembly 104 can be used as a replacementlighting assembly in existing fixtures that use fluorescent light bulbs.Alternatively, as will be detailed with respect to some embodiments ofthe disclosure, the lighting system and lighting assemblies can beprovided as a completely new fixture that can, for example, replace anexisting lighting fixture or to retrofit an existing lighting fixture.FIG. 5 illustrates an existing lighting fixture 114 typically used withfluorescent light bulbs that has been retrofitted with two lightingassemblies 104 (herein also called LED light bulbs or lamps) mounted inthe fixture 114. Although not seen in the photo, the lighting fixturehas also been retrofitted to include the power supply module (not shown)so as to power the lighting assemblies 104. It is to be appreciated thatlighting fixture 114 can also optionally be retrofitted with themulti-setting switch 110 and the sensor 106. The lighting assemblies 104can be used to replace existing 2-foot, 4-foot. 8-foot or any otherlength tubular fluorescent light bulbs and are configured to mate withexisting light fixture 114 connections for fluorescent light bulbsthrough end caps 112, and in at least one embodiment disclosed herein,to be powered through one end cap, as will be discussed herein. FIG. 6is a mechanical drawing of one embodiment of the end cap 112. Thus, anexisting light fixture 114 can be retrofitted with al east the powersupply module 102 and the light assemblies 104 can be plugged intostandard fluorescent light bulb sockets (now powered by power supplymodule 102) so as to convert a fluorescent light bulb fixture to an LEDlighting system according to this disclosure.

FIG. 7 is a photo of perspective view of an LED light assembly 104without one of its end caps 112 and without its cover 116. The LED lightassembly 104 includes the base 118 and a multi-layer circuit board 120that holds a plurality of LED chips 122. FIG. 8 is a photo of a top viewof the multi-layer circuit board 120 including the plurality of LEDchips 122, which can be slid into engagement with the base 118 along thedirection of the arrows 123. FIG. 9 is a photo of a perspective view ofthe base 118. FIG. 10 is a photo of a perspective view of a bottom ofthe base 118. And FIG. 11 is a mechanical drawing of the base 118. Ascan be seen in FIGS. 9-11, the base 118 includes arms 119 configured toreceive the multilayer circuit board 120, which can be slid intoengagement with the base 118 starting at the end of the base 118.

Referring again to FIG. 7, the multi-layer board 120 includes aplurality of LED chips 122. In the illustrated embodiment there are twoparallel traces of LED chips 122 spaced apart along a length of theboard so that there are two rows of LED chips that make up a 2-foot longsection of the multi-layer circuit board. According to one embodiment,each row of LED chips that make up the 2 foot long multi-layer circuitboard can include 25 LED chips. These 2 foot long multi-layer boards canbe combined in series within varying length bases to make up LED lightassemblies that are 2-foot long, 4-foot long, 8-foot long or anymultiple of 2-feet, along with respective 2-foot long, 4-foot long and8-foot long or any multiple of 2-feet long bases 118 and covers 116, toyield 2-foot long, 4-foot long, 8-foot long or any multiple of 2-feetlong LED light assemblies. It is also to be appreciated that themulti-layer boards, bases, and covers can be any length to provide anylength lighting assemblies.

FIG. 12 is a schematic diagram of one embodiment of two LED arrays 124,126 including a plurality of LED chips 122 that are housed by amulti-layer circuit board 120. It is to be appreciated that each LEDchip 122 includes a plurality of LED devices. It is also to beappreciated that each trace can include any number of LED chips 122 and5 LED chips 122 are illustrated for exemplary purposes only. FIG. 13 isa CAD/CAM rendering of a plurality of layers 128 of the multi-layerboard circuit 120. It can be seen from the photo of FIGS. 7 and from themulti-layer circuit board layout of FIG. 13 that the LED chips 122 arespaced apart along the length of the multi-layer circuit board 120.According to aspects of this embodiment of the light assembly 104, thespacing of the LED chips 122 and the layout of the multiple layers ofthe multi-layer circuit board 128 have been configured to maximize theamount of conductors on the layers of the board for dissipating heat, sothat the LED chips 122 remain cool during operation. In particular, inone embodiment, it is desirable to keep the LED chips below atemperature of no more than 42 degrees C. With this arrangement of themulti-layer board and spacing of the LED chips 122, it has been testedand verified that the LED chips are running at or below a temperature of41.6 degrees C. As a result of the spacing of the LED chips and thelayout of the multi-layer circuit board, it has been tested and verifiedthat the Luminous Efficiency of the LED light assembly 104 is at least105 LM/Watt. Contrast this with other LED light bulbs or lamps in thestate of the art that run at much higher temperatures and that have amuch lower Luminous Efficiency. Because the LED light assembly of thedisclosure runs below a temperature of 41.6 degrees C., it as anadvantage that the light assembly of the disclosure has a much longerlifetime (lasts a lot longer) than LED bulbs or lamps that run at ahigher temperatures. In particular, the applicants have designed the LEDlight assembly 104 to take advantage of the natural properties of LEDchips 122 that run below a temperature of 41.6 degrees C. or lower.Another advantage of the LED light assembly 104 according to thisdisclosure is that the assembly is configured to take advantage of thefact that the LED chips 122 provide a directed light output (they arenot omni-directional) and thus the LED light bulbs or lamps have ahighly directional light output of at least 105 LM/Watt. Still anotheradvantage of the LED light assembly 104 according to the disclosure isthat the LED light assembly does get hot, even after prolonged use, theyremain cool to the touch. This also saves on energy as the lightassemblies 104 do not radiate heat, and thus there are reduced airconditioning costs when using the LED light assemblies and the lightingsystems in air conditioned locations and climates.

FIG. 14 is a mechanical drawing of the cover 116 of the LED lightassembly 104 (see FIG.′ 2 for a perspective view of the cover). FIG. 33illustrates another embodiment of the cover 116 that covers theindividual light assemblies 104. The cover illustrated in FIG. 2 iswhite and is to some degree translucent and to some degree opaque tolight emitted by the plurality of LED chips 122 of the parallel LEDarrays 124, 126. However, it is also to be appreciated that the covercan also be clear as illustrated in FIG. 33, translucent, or colored. Itis also to be appreciated that the cover 116 can be provided withcorrugations along the length of the cover as illustrated in FIG. 33that result in disbursement of light from the light assemblies 104 alongthe width of the light assembly and cover (as shown in FIG. 33).

As noted above, the lighting assembly 100 includes a power supply 102,which is configured in combination with the LED light assemblies 104 toretro-fit or replace existing overhead light fixtures 114 so that theLED light assemblies 104 can be used in the existing overhead lightfixtures 114 or in various embodiments of the lighting system disclosedherein. FIG. 15 is a schematic view and FIG. 16 is a photo of aperspective of one embodiment of a power supply module according to thedisclosure. The power supply module comprises various sub-circuitsincluding an over current, rectifying and smoothing circuit 136, amicro-controller circuit 138, a stable current and voltage maintenancecircuit 140, and a controller circuit 108, that will be furtherdiscussed herein. As can be seen from the simplified schematic diagramon the top of the power supply module of FIG. 16, the power supplymodule receives a standard 120 Volts AC input signal on input line 130and converts the standard input voltage and current to two paralleloutput DC voltage signals on lines 132, 134 to power two LED lightassemblies 104.

Referring to FIG. 17, the power supply module 102 includes a fuseprotection circuit 136 that limits an overflow of current to the powersupply, for example on initial connection of a 120 volt AC signal to thelight assembly 104. In particular, the fuse limits peak current to thepower supply when the AC signal is initially connected and maintains aninstantaneous short-circuit due to an over current situation. Itprotects against possible fire or damage to parts by preventing aninflow of over current. The fuse protection circuit 136 also includes arectifying and smoothing circuit. The rectifying and smoothing circuitrectifies smoothes and filters the 120-240 VAC input signal to provide arectified DC signal and to eliminate any high frequency noise. Inparticular LF1, C2, LI2 are a conduction noise filter that eliminateshigh frequency noise generated from the AC input signal. D1 rectifiesthe input AC signal and converts the rectified signal to DC. The powersupply 102 also includes an RDC snubber circuit, which limits the peakvoltage provided to the drain of the MOSFET, as known to those of skillin the art, for example when the controller is switched off.

Referring to FIG. 18, the power supply module includes themicrocontroller circuit 138. The micro-controller circuit 138 includes acontroller chip 139 that receives input signals and controls a dutywidth of signals provided at an output and in combination with the FETQ1 to limit the maximum output current provided by the power supplymodule 102. The power supply module also includes a secondaryrectification circuit that rectifies through diode D5 high frequencypower generated from switching the IC controller 139 and smoothes thisenergy to a DC signal with capacitor C16. Further, the power supply alsoincludes an output voltage maintenance circuit that maintains 24 Voltsthrough the Zener Diode ZD1 and controls the current at the photodiodePC1 to maintain a stable output voltage.

The power supply also includes a stable current and voltage maintenancecircuit 140, which is illustrated in FIG. 19. The stable current andvoltage maintenance circuit divides the output signal from thecontroller circuit 108 and smoothing circuit 136 into master and slavesignals with stable currents that limit the maximum current and voltageto be provided to the LED light bulbs or lamps 104. The constant currentcontrol provides a constant current to each LED chip 122 of the LEDlight bulb 104. In particular, even if one of the LED chips fails (forany reason), the constant current control circuit maintain a constantcurrent to the other LED chips in the array (the current doesn'tincrease), so that the LED chips are operating at an ideal constantcurrent and voltage. One advantage of this circuit is that even if oneor more LED chips in the array of chips fails, such failure will notresult in acceleration of the failure of the remaining LED chips. Thus,the LED array of chips will have a lifetime of the individual LED chipsand a longer lifetime than prior art LED devices that do not have suchconstant current and voltage control.

FIG. 20 illustrates an embodiment of the sensors 106 that can optionallybe provided as part of the lighting system 100 (see schematic diagram ofFIG. 1) and that can be mounted in an existing light fixture 114 (Seealso FIG. 6 for a view of the sensors 106 mounted in the light fixture114). FIG. 21 is a schematic diagram of the sensors circuits that can beused with the sensors 106. The sensor circuit includes a motion sensorcircuit 144 that detects motion to provide for turning on the LED lightbulbs or lamps 104 in response to the detected motion. The sensorcircuit also includes an ambient light sensor circuit 142, which outputsa signal corresponding to an amount of detected ambient light. FIG. 22is a schematic diagram of the microcontroller circuit 108 (See FIG. 1).The microcontroller circuit 108 in combination with the motion sensor142 of sensors 106, combine to provide an output signal that turns onthe LED light bulbs or lamps 104 in response to motion detected by themotion sensor. In addition, the microcontroller 108 in combination withthe light sensor 142 of sensors 106, combine to provide an output signalthat adjusts the amount of light output by LED light bulbs or lamps 104.For example, if no ambient light is detected by the light sensor 142,then the light bulbs or lamps can provide a maximum light output.Alternatively, if a sufficient amount of ambient light is detected, suchas may occur in daylight, then LED light bulbs or lamps can becontrolled, for example to only provide half of the light capacity ofthe LED light bulbs or lamps. It is to be appreciated that thecontroller can be configured to control the amount of light to be outputby the LED light bulbs or lamps to a desired level and as a function ofthe amount of ambient light detected. One advantage of this aspect ofthe lighting system 100 of the disclosure is that the amount of powerconsumed by the lighting system can be reduced in response to an amountof ambient light, thus providing for energy savings (reduced powerconsumption) as a function of ambient light conditions.

It is to be noted that the LED light assemblies 104 according to thisdisclosure provide a lot more light than is typical for fluorescentlight bulbs or lamps that they are intended to replace. In particular,it has been measured and tested that an existing fixture 114 retrofittedwith 2 LED assemblies 104 according to this disclosure provides a lotmore light than the same fixture having 3 fluorescent bulbs. Thus it maybe desirable depending on the location of the existing fixture 114 to beretrofitted or a new lighting fixture comprising the lighting system ofthis disclosure to dim the maximum amount of light provided by thefixture provided with the LED light assemblies 104. FIG. 23 illustratesa schematic diagram of one embodiment of the multi-position switch 110(See FIG. 1). Referring to FIG. 1, the power supply module 102 and themicrocontroller 108 in combination with the multi-position switch 110combine to provide an output signal that adjusts the amount of lightoutput by each of the LED light assemblies 104. For example, an existingfixture 114 as illustrated in FIG. 5 retrofitted with 2 LED lightassemblies 104 and the lighting system 100 including the multi-positionswitch 110, can be set at the time of retrofitting and installing thefixture to a maximum light output that is appropriate for the fixturelocation and that can be less than 100% capacity of the two LED lightassemblies 104. Thus another advantage of this aspect of the lightingsystem of the disclosure is that the amount of power consumed by thelighting system can be reduced depending on the fixture location, thusproviding for energy savings (reduced power consumption) as a functionof fixture location and an amount of light needed.

For example, referring to FIG. 24, there is illustrated one embodiment atable of a maximum output current provided by the controller circuit 108and the power supply module 102 to the LED light assembly 104 inresponse to the, output signal from the multi-position switch 110,having 3 switches (SW3, SW2, SW1). The switch setting provides foroperating the assembly in various modes. For example, referring to row2710, for a switch setting of 001 (SW3, SW2, SW1), the assembly isconfigured to sense ambient light conditions with sensor 106 (seeFIG. 1) and ambient light sensor circuit 142, and provide a maximumoutput current of 550 mAmps; referring to row 2712, for a switch setting(SW3, SW2, SW1) of 010, the assembly is configured to sense ambientlight conditions with sensors 106 (see FIG. 1) and ambient light sensorcircuit 142, and provide a maximum output current of 500 mAmps;referring to row 2714, for a switch setting of 100 (SW3, SW2, SW1), theassembly is configured to sense ambient light conditions with sensors106 (see FIG. 1) and ambient light sensor circuit 142, and provide amaximum output current of 450 mAmps. For each of these switch settings(SW3, SW2, SW1), the microcontroller 108 and power supply 102 areconfigured to provide an output current to the LED light assembly thatis stepped over a voltage range from the maximum current valueconfigured by the switch to a minimum current value (for example 250mAmps) as a function of a sensed amount of ambient light sensed by thesensors 106 and ambient light sensor circuit 142 of the environment thatthe lighting system 100.

For example, referring to FIG. 25, for the switch configured with a 001(SW3, SW2, SW1) setting (2810), the maximum output current provided bythe controller 108 and power supply module 102 is 550 mAmps (2812) witha sensed voltage CDS (See also FIG. 23) from an ambient light sensor of<1.46 V (2814), which corresponds to a minimum amount of ambient light.With a sensed voltage CDS from an ambient light sensor of 1.46V<CDS<1.7V(2816), which corresponds to more ambient light, the maximum outputcurrent provided by the controller 108 and power supply module 102 isstepped down to 525 mAmps (2818), which provides less light by the LEDlight assembly 104 and less power consumption. Further, with a sensedvoltage CDS from an ambient light sensor of 1.7V<CDS<1.95V (2820), whichcorresponds to even more ambient light, the maximum output currentprovided by the power supply 102 is stepped down further to 510 mAmps(2822), which provides even less light by the LED lamp and even lesspower consumption. The controller 108 is configured with this process ofstepping down the maximum output current provided by the power supplymodule 102 as function of the sensed voltage CDS from an ambient lightsensor, and has a total of 9 steps all the way up to a sensed voltageCDS from an ambient light sensor of >3.173V (2824), which corresponds toa maximum amount of ambient light and a minimum amount of output currentprovided by the power supply 102 of 250 mAmps (2826), which providesminimum light by the LED lamp for maximum ambient light conditions.

Another embodiment is illustrated with respect to FIG. 26 for the switchconfigured with a switch (SW3, SW2, SW1) setting of 010 (2910). For thissetting of the switch, the maximum output current provided by the powersupply 102 is 500 mAmps (2912) with a sensed voltage CDS (See also FIG.23) from an ambient light sensor of <2.197 Volts (2914), whichcorresponds to a minimum amount of ambient light for this switchsetting. With a sensed voltage CDS from an ambient light sensor of2.197V<CDS<2.44V (2916), which corresponds to more ambient light, themaximum output current provided by the power supply 102 is stepped downto 475 mAmps (2918), which provides less light by the LED lamp and lesspower consumption. Further, with a sensed voltage CDS from an ambientlight sensor of 2.44V<CDS<2.685V (2920), which corresponds to even moreambient light, the maximum output current provided by the power supply102 is stepped down further to 450 mAmps (2922), which provides evenless light by the LED lamp and even less power consumption. Thecontroller 108 is configured with this process of stepping down themaximum output current provided by the power supply module 102 asfunction of the sensed voltage CDS from an ambient light sensor and hasa total of 6 steps all the way up to a sensed voltage CDS from anambient light sensor of >3.173V (2924), which corresponds to a maximumamount of ambient light and a minimum amount of output current providedby the power supply 102 of 250 mAmps (2926), which provides minimumlight by the LED light assembly 104 for maximum ambient lightconditions.

Another embodiment is illustrated with respect to FIG. 27 for the switchconfigured with a switch (SW3, SW2, SW1) setting of 100 (3010). For thissetting of the switch, the maximum output current provided by thecontroller 108 and power supply 102 is 450 mAmps (3012) with a sensedvoltage CDS (See also FIG. 23) from an ambient light sensor of <2.685Volts (3014), which corresponds to a minimum amount of ambient light forthis switch setting. With a sensed voltage CDS from an ambient lightsensor of 2.685V<CDS<2.929V (3016), which corresponds to more ambientlight, the maximum output current provided by the power supply 102 isstepped down to 375 mAmps (3018), which provides less light by the LEDlight assembly 104 and less power consumption. The controller 108 isconfigured with this process of stepping down the maximum output currentprovided by the power supply module 102 as function of the sensedvoltage CDS from an ambient light sensor, and has a total of 4 steps allthe way up to a sensed voltage CDS from an ambient light sensorof >3.173V (3020), which corresponds to a maximum amount of ambientlight and a minimum amount of output current provided by the powersupply 102 of 250 Amps (3022), which provides minimum light by the LEDlamp for maximum ambient light conditions.

Referring again to FIG. 24, there are also illustrated settings for theswitch 110 that configure the controller 108 of the lighting system 100to operate in a motion detection mode and to provide a correspondingmaximum output current provided by the power supply module 102 to theLED light assembly 104 as a function of the switch 110 settings. Theswitch setting and controller 108 provides for operating the lightassembly 104 in various brightness and power consumption modes based onmotion detection. For example, referring to row 2716 as will beexplained in further detail below, for a switch setting (SW3, SW2, SW1)of 011, the assembly is configured to sense motion with sensors 106 (seeFIG. 1) and provide a maximum output current of 550 mAmps; referring torow 2718, for a switch setting (SW3, SW2, SW1) of 110, the assembly isconfigured to sense motion with sensors 106 (see FIG. 1) and provide amaximum output current provided is 500 mAmps; referring to row 2720, fora switch setting (SW3, SW2, SW1) of 101, the assembly is configured tosense motion with sensors 106 (see FIG. 1) and provide a maximum outputcurrent of 450 mAmps. For each of these switch 110 settings, themicrocontroller 108 and power supply 102 are configured to provide amaximum output current to the LED lamp as a function of sensed motion.

For example, referring to FIG. 28, for the switch configured with a 011(SW3, SW2, SW1) setting (3110), the maximum output current provided bythe power supply 102 is 550 mAmps (3112) in response to sensed motion(3114 YES) with sensors 106 (see FIG. 1) and motion sensor circuit 144,and otherwise a minimum output current of 250 mAmps is provided (3116)by the power supply module 102 in response to no sensed motion (3114 NO)with sensors 106 and motion sensor circuit 144. Referring to FIG. 29,for the switch configured with a 101 (SW3, SW2, SW1) setting (3210), themaximum output current provided by the power supply module 102 is 450mAmps (3212) in response to sensed motion (3214 YES) with sensors 106and motion sensor circuit 144 (see FIG. 1) and otherwise a minimumoutput current of 250 mAmps is provided (3216) by the power supplymodule 102 in response to no sensed motion (3214 NO) with sensors 106and motion sensor circuit 144. Similarly, referring to FIG. 30, for theswitch configured with a 110 setting (3310), the maximum output currentprovided by the power supply 102 is 500 mAmps (3312) in response tosensed motion (3314 YES) with sensors 106 (see FIG. 1) and motion sensorcircuit 144, and otherwise a minimum output current of 250 mAmps isprovided (3316) by the power supply module 102 in response to no sensedmotion (3314 NO) with sensors 106 and motion sensor circuit 144.

Referring again to FIG. 24, there are also illustrated settings (SW3,SW2, SW1) for the switch 110 that configure the lighting system 100 toprovide a predetermined amount of output current by the power supplymodule 102 to the LED light assembly 104 as a function of the switch 110settings. These switch settings provide for operating the assembly invarious fixed brightness and power consumption modes with no ambientlight sensing or motion detection. For example, referring to row 2722,for a switch setting (SW3, SW2, SW1) of 111, the assembly is configuredto provide a maximum output current of 550 mAmps. This setting wouldtypically be used for low ambient light conditions where no motionsensing or ambient light detection is being used. Referring to row 2724,for a switch setting (SW3, SW2, SW1) of 000, the assembly is configuredto provide an output current of 250 mAmps. This setting would typicallybe used for an environment with good ambient light conditions and whereno motion sensing or ambient light detection is being used or needed.

Another advantage of the controller 108 and the power supply module 102and the LED light assemblies 104 according to this disclosure is thatthey combine to have a substantially constant Power Factor or efficiencyof at least or greater than 99%, even when the amount of light output bythe LED assemblies 104 is dimmed. For example, the lighting system ofthis disclosure has been tested and shown to have a power factor orefficiency of the lamps that remains at least 95% when the lamp lightoutput is dimmed due to ambient light sensing by sensors 106 and ambientlight sensing circuit 142 or due to fixing the amount of light output byLED light bulbs or lamps 104 to be less than maximum with themulti-position switch 110.

FIG. 31 is a photo of a front view of another embodiment of a lightingsystem 150 according to this disclosure. This embodiment of the lightingsystem 100 includes two light assemblies 104 (the light assemblies donot have a cover 116 over the individual light assemblies), and a cover152 that covers the combination of both light assemblies 104. The cover154 is held in place by rods 154. The lighting system also includes areflecting background 156, a slot 158 for the sensors 106 (asillustrated in other embodiments). FIG. 32 is a photo of an explodedview of a portion of the light assembly 100 showing a portion of the twolight assemblies 104, a portion of the cover 152, and a portion of therods 154 As can be seen in FIG. 32, the cover 152 has corrugations alongthe length of the cover that result in disbursement of light from thelight assemblies 104 along the width of the light assemblies 104 andalong the width of the cover. The corrugations in the cover 152 aresimilar to the corrugations in the cover 116 as shown in FIG. 33. FIG.34 illustrates a rear view of the lighting system 150 having slots 160,162 in the reflector 156 (through which can be seen a portion of therespective backs of the bases 118 of the lights assemblies 104), whichare provided for allowing heat to escape the combination of the lightassemblies 104 and cover 152 so as to provide cooling of the overalllighting assemblies 104. Though not shown in FIG. 34, the lightingsystem also includes also includes the power supply module 102, themicro controller 108, and the multiple position switch 110, which canall be provided on the back side of the reflector 154 and within a frame164 and casing for the frame (not illustrated) that houses the overalllighting system 150. It is to be appreciated that the lighting systemcan also optionally comprise sensors 106, ambient light sensor circuit142, and motion sensor circuit 144.

Referring to FIG. 34, the lighting system 100 also includes bracket pins166 which can be inserted through the frame 164 and into the ends of thebases 118 of the lighting assemblies 104 so as to secure the lightingassemblies 104 to the frame 164. FIG. 35 shows a photo of an explodedview of the bracket pins 166 inserted into a portion of the frame 164.FIG. 36 shows a bracket pin 166 inserted into the end of the base 118 ofthe lighting assembly 104 (without the frame 166 obstructing the view).FIG. 37 is a mechanical drawing of the bracket pin 166. FIG. 38 ismechanical drawing of a portion of the frame 165 including slots 165,167 for receiving the bracket pin 166.

Referring again to the rear view of the lighting system 150 in FIG. 34,there can also be seen a hanging bracket 168 and mating clips 170, 172secured to the frame 164. FIG. 39 is a photo of a perspective view ofthe hanging bracket 168 and FIG. 40 is a mechanical drawing of thehanging bracket 168. The hanging bracket 168 in combination with theclips are used to secure the hanging bracket 168 to the frame 164 and tosecure the frame 164 and the lighting system 150 to a casing for theframe (not illustrated) that houses the overall lighting system 150. Inparticular the hanging bracket 168 and clips 170, 172 mate together toallow the hanging bracket 168 to easily be connected and disconnectedfrom the clips 170, 172 at both ends of the frame 164 of lighting systemto allow for easy installation and wiring of the overall lighting system150. In particular, the hanging bracket 168 and clips 170, 172 allow forone or both ends of the lighting system to easily be connected anddisconnected from the casing for the frame (not illustrated) that housesthe overall lighting system 150. With this arrangement, for example, oneend of the lighting system can be disconnected from the casing while theother end of the frame remains connected to the casing so as to allowthe disconnected end of the lighting system 150 to easily be pivoteddownwards to hang freely while the other end of the lighting system 150remains connected to the casing. This arrangement of the hangingbrackets thus allows for easy installation and wiring of the overalllighting system 150 without having to hold the overall lighting systemwhile wiring or installing it.

FIG. 41 is a photo of a perspective view of another embodiment of alighting system 170 according to this disclosure. This embodiment of thelighting system includes two light assemblies 104 (without a cover 116over the individual light assemblies 104), and a cover 172 over thecombination of both light assemblies 104. FIG. 41 illustrates anembodiment of the cover 172 that covers the individual light assemblies104, which has corrugations along the length of the cover much the sameas previously shown in FIG. 2 and FIG. 33. In particular, similar to thecover 116 and the cover 154, the cover 172 can have corrugations runningalong the length of the cover that help to disburse the light in adirection along the width of the cover 172 and along the width of thelighting system 170. According to this embodiment, the cover 172 is heldin place by clips 174 and corresponding mating base of the clips whichare secured to a base 186 (See in FIG. 43) of the lighting system 170.Referring to FIG. 42, this embodiment of the lighting system 170 canalso optionally include a holding structure 176 for holding sensors 106and providing a conduit for coupling the sensor 106 (as illustrated inother embodiments) to the controller 108 of the power supply module 102.In particular, as can be seen in FIG. 43 the lighting system 170includes the power supply module 102 housing the micro controller 108,and the multiple position switch 110, which can all be provided on aback side of the frame 178 for holding the light assemblies 104 andwhich can be housed within the base 186 of the overall lighting system170. Referring to FIG. 43, the power supply module 106 can be housedwithin the lighting system 170, for example, on a back side of a baseplate 178 that secures the lighting assemblies 104. FIG. 44 is anexploded view of a front view of a portion of the lighting system 170without its cover 172, showing a portion of the two light assemblies 104secured to the base plate 178 by rounded snap brackets 180. Referring toFIG. 45, there is illustrated a mechanical drawing of a perspectiveview, side view and bottom view of the rounded snap brackets 180, whichcan be secured to the base plate 178 through an aperture 182 in therounded snap bracket with hardware 184. It is appreciated that hardware184 can be a screw, a rivet, a plug, a clip, an insert or any other formof hardware typically used to secure a bracket to a plate. The lightingassemblies 104 are shown with end caps 112, which have been discussedwith respect to other embodiments herein, and which provide forelectrically connecting the lighting assemblies 104 to the power supplymodule 102 through end caps 112. According to this embodiment, wires 184run through the connectors 182 to connect the light assemblies 104 tothe power supply module 102. FIG. 46 shows a perspective view, end viewand schematic view of the connector 182 that is used to connect lightingassembly 104 to the power supply module 102. It is to be appreciatedthat the embodiments of the lighting assemblies 104 shown in FIG. 44have covers 116 covering the base 118 and board 120 (as illustrated inother embodiments herein). However it should be appreciated that thecovers 116 are not necessary and preferably are not used simultaneouslywith cover 172. It should also be appreciated that cover 172 is optionaland may not be used in certain installations where weather is not afactor, such as for example parking garages.

Various alterations, modifications, and improvements can be made to thelighting system of this disclosure. By way of example, referring to theschematic diagram of FIG. 1, the power supply module 102 can includesthe microcontroller 108 and the switch 110, or the multi-position switch110 can be separate from the power supply 102. In addition, it is to beappreciated that the switch can be, for example, an electronicallycontrolled switch, or a mechanical DIP switch. Further, it is to beunderstood the LED chips 122 can be all one color, such as white orother wavelength bands such as red, or can be different colors, such asfor example, red and white interleaved so as to provide for red or whiteoverhead light. Further, it is to be appreciated that additional LEDchips of a different color, such as red, can be provided, where the LEDchips of the multi-layer board 120 disclosed are all white, so as toprovide a multi-color LED light bulb 104.

Having described above several aspects of at least one embodiment, it isto be appreciated various alterations, modifications, and improvementswill readily occur to those skilled in the art. Such alterations,modifications, and improvements are intended to be part of thisdisclosure and are intended to be within the scope of the invention.Accordingly, the foregoing description and drawings are by way ofexample only.

What is claimed:
 1. An LED based lighting system, comprising: at leastone light assembly comprising a plurality of LED chips; a controllerconfigured to receive an input signal and to provide an control signalfor controlling the at least one light assembly; and a power supplymodule configured to receive a standard voltage and current signal, toconvert the standard voltage and current signal to a DC voltage signalfor powering the controller and to provide a power signal to the atleast one light assembly to power the at least one light assembly inresponse to the control signal; wherein the power supply comprises aconstant current maintenance circuit that limits the maximum currentprovided to the at last one light assembly so that even if any one ormore LED chips of the plurality of LED chips fail, the constant currentcontrol circuit maintains a constant current to a remainder of theplurality of LED chips of the at least one light assembly so that theremainder of the plurality of LED chips continue to operate at aconstant current.
 2. The LED based lighting system as claimed in claim1, further comprising a remote controller housing a plurality of switchsettings that provide a respective switch output signal for each switchsetting; and wherein the controller is responsive to switch outputsignal and is configured to provide the control signal to control amaximum light level provided by the at least one light assembly inresponse to the setting of the plurality of switch settings.
 3. The LEDbased lighting system as claimed in claim 2, further comprising aambient light sensor that senses an amount of ambient light and providesan ambient light sensor output signal as a function of an amount ofsensed ambient light; and wherein the controller is also responsive tothe ambient light sensor output signal and is configured to provide thecontrol signal to control the light level provided by the at least onelight assembly to reduce the amount of light output from the maximumlight level to a reduced light level in a plurality of steps in responseto the amount of sensed ambient light.
 4. The LED based lighting systemas claimed in claim 2, further comprising a motion sensor that sensesmotion and provides a motion sensor output signal; and wherein thecontroller is also responsive to the motion sensor output signal and isconfigured to provide the control signal to control the maximum lightlevel provided by the at least one light assembly in response to sensedmotion.
 5. The LED based lighting system as claimed in claim 1, whereinthe at least one light assembly is sized and configured to bereplacement for a standard fluorescent light bulb.
 6. The LED basedlighting system as claimed in claim 1, wherein the lighting systemcomprises a housing that is sized and configured to be a replacement fora standard overhead light fixture.
 7. The LED based lighting system asclaimed in claim 6, wherein the power supply module is external to theat least one light assembly and housed within the housing.
 8. The LEDbased lighting system as claimed in claim 7, wherein the at least onelight assembly comprises a circuit board housing a plurality of LEDchips arranged in at least one row, wherein the circuit board isconfigured so as to dispose the plurality of LED chips in a spaced apartrelationship so as to keep the LED chips below a maximum operatingtemperature.
 9. The LED based lighting system as claimed in claim 8,wherein the circuit board is laid out so to keep the chips below atemperature of 41 C.
 10. The LED based lighting system as claimed inclaim 8, wherein the efficiency of the at least one light assembly is atleast 125 Lumens/Watt.
 11. The LED based lighting system as claimed inclaim 8, wherein the at least one light assembly further comprises abase having a plurality of arms that define ridges along the length ofthe base to receive the circuit board.
 12. The LED based lighting systemas claimed in claim 11, wherein the at least one light assembly furthercomprises at least one end cap.
 13. The LED based lighting system asclaimed in claim 6, wherein the lighting system comprises at least twolight assemblies.
 14. The LED based lighting system as claimed in claim13, further comprising a cover that covers that at least two lightassemblies, wherein the cover has ridges running along a length of thecover so as to disperse the light provided by at least two lightassemblies along a width of the cover and along a width of the lightingsystem.
 15. The LED based lighting system as claimed in claim 14,further comprising two rods that maintain the cover in place over the byat least two light assemblies.
 16. The LED based lighting system asclaimed in claim 15, further comprising a reflective background havingridges to reflect the light provided by the at least two lightassemblies.
 17. The LED based lighting system as claimed in claim 6,further comprising: a frame of the housing of the lighting system havinga plurality of slots in two ends of the frame; and a bracket pin, eachbracket pin being shaped and arranged to be pushed through correspondingof the plurality of slots in the frame and into an end of a base of theat least one light assembly.
 18. The LED based lighting system asclaimed in claim 17, further comprising a respective hanging bracket andtwo clips for each of the two ends of the frame of the lighting systemthat are constructed and arranged to allow for easy installation andremoval of each end of the frame of the lighting system to a casing forthe lighting system.
 19. The LED based lighting system as claimed inclaim 6, further comprising a plurality of clamps that maintain a coverto the housing of the lighting system.
 20. The LED based lighting systemas claimed in claim 1, wherein the at least one light assembly furthercomprises a cover having ridges running along a length of the cover soas to disperse the light provided by the plurality of LED chips along awidth of the cover and the light assembly.